FR3062710A1 - CORROSIVE FLUID HEATER FOR METALS, RESERVOIR, AND MANUFACTURING METHOD THEREFOR. - Google Patents

Abstract

The subject of the invention is a heater (1) for a corrosive fluid comprising at least one heat diffuser (2) having at least a first portion (2a) intended to be immersed in a corrosive fluid, and at least one second portion (2b) intended to be arranged out of the corrosive fluid, at least one heating block comprising at least one heating member (5) configured to heat the corrosive fluid, said diffuser (2) comprising at least one housing (3) in wherein the at least one heating block is housed at least partially, at least the first portion (2a) of the diffuser (2) being made of anodized aluminum or anodized aluminum alloy and is configured to be in direct contact with the fluid corrosive. The invention also relates to a corrosive fluid reservoir comprising a heater according to the invention and a method of manufacturing a diffuser of the heater according to the invention.

Description

© Publication no .: 3,062,710 (to be used only for reproduction orders)

©) National registration number: 17 50959 ® FRENCH REPUBLIC

NATIONAL INSTITUTE OF INDUSTRIAL PROPERTY

COURBEVOIE © Int Cl ⁸ : F24 H1 / 20 (2017.01), B 65 D 88/74, F 01 N 3/08, 3/20

A1 PATENT APPLICATION

©) Date of filing: 06.02.17. (© Priority: (© Applicant (s): MGICOUTIER Société anonyme - FR. ©) Date of public availability of the request: 10.08.18 Bulletin 18/32. @ Inventor (s): LAMIRAN D YVES and JAQU ET SYLVAIN. ©) List of documents cited in the preliminary search report: See the end of this booklet (© References to other related national documents: ©) Holder (s): MGI COUTIER Société anonyme. ©) Extension request (s): © Agent (s): CABINET GERMAIN & MAUREAU.

164) CORROSIVE FLUID HEATER FOR METALS, TANK AND MANUFACTURING METHOD THEREOF.

FR 3 062 710 - A1 (6 /) The subject of the invention is a heater (1) for a corrosive fluid comprising at least one heat diffuser (2), having at least a first portion (2a) intended to be immersed in a corrosive fluid, and at least a second portion (2b) intended to be arranged outside the corrosive fluid, at least one heating block comprising at least one heating element (5) configured to heat the corrosive fluid, said diffuser (2 ) comprising at least one housing (3) in which the at least one heating block is housed at least partially, at least the first portion (2a) of the diffuser (2) being made of anodized aluminum or of an anodized aluminum alloy and is configured to be in direct contact with the corrosive fluid.

The invention also relates to a corrosive fluid reservoir comprising a heater according to the invention and a method of manufacturing a diffuser of the heater according to the invention.

i

The present invention relates to the technical field of storage systems for corrosive fluids, in particular for certain metals, for example aluminum or iron. In the present application, the expression “corrosive fluid for certain metals” will be understood to mean a fluid which can lead to chemical degradation of these metals in contact with this fluid.

In particular and for example, the present invention relates to the technical field of storage systems and pressurization and / or supply of a solution used in the process of selective catalytic reduction (SCR) of motor vehicles, heavy goods vehicles, agricultural machinery and construction machinery. This solution is a diesel exhaust fluid known under the standard name AUS 32 for "Aqueous Urea Solution" in English and "Aqueous Urea Solution" in French and also sometimes called commercially Adblue®. This solution includes 32.5% highly pure urea diluted in demineralized water, making it possible to convert nitrogen oxides NO _X contained in the exhaust gases, into nitrogen and water vapor, thus reducing emissions. polluting vehicles.

Generally, the aqueous urea solution is stored in a dedicated tank in the vehicle which is connected to the selective catalytic reduction system of said vehicle.

In the present invention, the term “selective catalytic reduction system” will be understood to mean a system comprising a reservoir of an aqueous urea solution, a catalyst, an injector of the aqueous urea solution in the exhaust line and at least minus one pipe connecting the reservoir to the injector, the catalyst being positioned at the level of the exhaust line downstream of the inlet of the injector so that catalysis takes place on a mixture of exhaust circulating in the exhaust line and aqueous urea solution injected upstream of the catalyst in said exhaust line.

In known manner, the aqueous urea solution contained in a storage device of a vehicle tends to freeze around -11 ° C. As a result, the device for storing aqueous urea solution is generally equipped with a system for reheating said solution in order to prevent the latter from freezing.

There are several types of aqueous urea solution heaters. For example, preferably for heavy vehicles, the calories of the engine cooling system are used by means of a stainless steel plunger used as a heat exchanger submerged in the tank. To date, this solution has not been used for light motor vehicles since the aqueous urea solution tank is located opposite the engine cooling system, which requires long pipelines running through the whole vehicle and therefore bulky. In addition, making stainless steel plungers is expensive and complicated.

In addition, there are also heating devices comprising one or more heating elements, such as resistive tracks or thermistors with a positive temperature coefficient called PTC in the rest of this application, whether or not equipped with an aluminum heat diffuser. for example, the assembly being overmolded with a compatible material for immersion in the aqueous urea solution, such as silicone, polyoxymethylene (POM) or high density polyethylene (HDPE). These overmolded devices have several drawbacks. The plastics, generally thermoplastics, used for overmolding generally have relatively low melting temperatures, which results in a limitation of the power density of the devices to prevent the overmolding from melting, which leads to an increase in the exchange surfaces. and therefore a large footprint. In addition, the plastics used are generally poor thermal conductors, which reduces the efficiency of the heaters. Finally, these plastics having a coefficient of expansion different from resistive tracks or diffusers, there is a significant risk of the appearance of cracks, ruptures or detachment from the overmolding making the heater ineffective, or even ineffective.

The invention aims to remedy all or part of the aforementioned drawbacks.

The subject of the invention is a corrosive fluid heater for metals, for example an aqueous urea solution, comprising:

at least one heat diffuser, having at least a first portion intended to be immersed in a corrosive fluid for metals, for example an aqueous urea solution, and at least a second portion intended to be arranged outside the corrosive fluid,

- At least one heating block comprising at least one heating member configured to heat the corrosive fluid, said diffuser comprising at least one housing in which the at least one heating block is housed at least partially, characterized in that at least the first portion of the diffuser is made of anodized aluminum or anodized aluminum alloy and is configured to be in direct contact with the corrosive fluid.

The heater according to the invention has several advantages. Indeed, by using a diffuser of which at least the first portion is made of anodized aluminum or of an anodized aluminum alloy, one overcomes a plastic overmolding which slows down the heating of the corrosive fluid. In addition, possible faults and cracks due to a difference in coefficient of thermal expansion are avoided since the diffuser is made of mono-material without overmolding. Thus, the heater according to the invention makes it possible to combine high thermal conduction properties thanks to the use of aluminum and protection by anodization of this same aluminum against a corrosive fluid chemically degrading aluminum, such as, for example, an aqueous urea solution.

In addition, the melting temperature of aluminum and the cracking temperature of the anodized layer being higher than the melting temperatures of the overmolding materials, the anodized heater according to the invention can be brought to temperatures higher than those usually used for overmolded heaters, and therefore limit the space required by the heater according to the invention.

According to a characteristic of the invention, the corrosive fluid is an aqueous solution of urea.

According to a characteristic of the invention, the first portion of the diffuser is not molded from a plastic material.

According to a characteristic of the invention, the material used for the production of the diffuser can be an aluminum alloy such as A-S9U3 (Fe). The term aluminum alloy A-S9U3 (Fe) is understood to mean an aluminum-silicon alloy with copper having the name A-S9U3 (Fe) which is similar internationally, to the alloy A380 in the United States and to the alloy ADC10 in Japan.

According to a characteristic of the invention, the material used for the production of the diffuser can be an aluminum alloy such as aluminum alloys 6082, 6351, 6063, which are aluminum-magnesium-silicon alloys.

According to a characteristic of the invention, the material used for the production of the diffuser can be an aluminum alloy such as aluminum alloys 5083, 5754, which are aluminum-magnesium alloys.

Advantageously, the diffuser made of one of the alloys of anodized aluminum or of anodized aluminum makes it possible to obtain very good performances of resistance to corrosion in the aqueous urea solution.

According to a characteristic of the invention, the heating block is in direct contact with the housing of the diffuser, that is to say that the heating block is devoid of overmolding, thus allowing a more efficient transmission of heat to the diffuser and faster.

According to a characteristic of the invention, the heating element is a resistive track or a thermistor with a positive temperature coefficient.

According to a characteristic of the invention, the heating block comprises a plurality of heating members housed in the housing of the diffuser.

Preferably, the heating block comprises at least four thermistors with a positive temperature coefficient.

According to a characteristic of the invention, the heating block comprises one or more fixing and / or holding elements configured to hold the heating member or members in the housing. For example, the fixing and / or holding element is a holding spring.

Preferably, the heating block comprises a support shaped to at least partially receive the heating members and preferably the thermistors with a positive temperature coefficient.

According to a characteristic of the invention, the support is configured to be inserted at least partially into the housing of the diffuser.

According to a characteristic of the invention, the heater comprises at least one connector element configured to connect the heater (s) to an electronic card.

According to a characteristic of the invention, the heating element or members are controlled by at least one electronic card.

According to a characteristic of the invention, the diffuser comprises at least one diffusion fin, which makes it possible to transfer the heat produced by the heating member into the corrosive fluid effectively.

According to a characteristic of the invention, the fin is arranged on the first portion of the diffuser.

Advantageously, the diffuser comprises a plurality of diffusion fins distributed over the first portion of the diffuser.

According to a characteristic of the invention, the second portion of the diffuser is at least partially not anodized.

According to a characteristic of the invention, the housing of the diffuser provided for the heater member (s) extends transversely between the first portion of the diffuser and the second portion of the diffuser. Advantageously, the housing of the diffuser extends in a secant plane, preferably substantially perpendicular, to the plane in which the first portion and / or the second portion of the diffuser generally extends.

Alternatively and according to a characteristic of the invention, the housing of the diffuser extends in a plane substantially parallel to the plane in which the first portion and / or the second portion of the diffuser generally extends.

Advantageously, the heating block is always located in the dry zone of the heater.

The subject of the invention is also a reservoir for a corrosive fluid for metals, for example an aqueous urea solution, the reservoir comprising:

an internal volume intended to contain a corrosive fluid for metals, for example an aqueous urea solution, said internal volume being delimited by at least one upper wall, a lower wall and a side wall connecting the upper wall and the lower wall,

a drawing orifice shaped to receive a drawing member for the corrosive fluid,

- A heater according to the invention, said heater being positioned on one of the walls of the tank, the first portion of the diffuser of the heater being arranged in the interior volume of the tank.

According to a characteristic of the invention, the first portion of the diffuser is positioned as close as possible to the withdrawal orifice, which allows the corrosive fluid to be drawn at the right temperature.

Preferably, the first portion of the diffuser is positioned on the bottom wall of the tank.

According to a characteristic of the invention, the second portion of the diffuser is arranged at least partially outside the tank.

According to a characteristic of the invention, the tank comprises a positioning orifice shaped to allow the arrangement of the heater partly in the interior volume of said tank and partly outside the tank.

According to a characteristic of the invention, the reservoir comprises a seal formed at the level of the positioning orifice so that the second portion of the diffuser is not in contact with the corrosive fluid contained in the reservoir.

According to a characteristic of the invention, said seal is formed integrally with said reservoir positioning orifice or said seal being formed independently with respect to said reservoir positioning orifice.

According to one characteristic of the invention, the heater comprises a seal formed at the level of the reservoir positioning orifice, said seal being formed integrally with said heater or said seal being formed independently with respect to said heater.

Alternatively or in addition and according to a characteristic of the invention, the diffuser comprises a seal, which is preferably overmolded on said diffuser.

Thus, according to the invention, the seal can be a seal independent of the components of the heater or of the reservoir, or else the seal is a seal inseparable from the diffuser or from another component of the heater or from the reservoir.

According to a characteristic of the invention, the connector element of the heater is protruding with respect to the reservoir and makes it possible to connect the electronic card which is arranged outside the reservoir with the heater member (s) housed in the housing of the diffuser.

The invention also relates to a method of manufacturing a heater diffuser according to the invention, said method comprising a step of producing the diffuser in a material of aluminum or aluminum alloy type and an anodizing step on at at least a first portion of said diffuser, said first portion being intended to be immersed in an aqueous urea solution.

The anodizing step makes it possible to give the diffuser thus formed good protection against the corrosivity of the aqueous urea solution and makes it possible to dispense with any part or additional material to be added to the diffuser to protect it.

Preferably, the anodization carried out in the manufacturing process of the diffuser is a hard anodization. “Hard anodization” is understood to mean anodization with a sulfuric acid bath, allowing good abrasion resistance and high hardness, this hard anodization is also known under the name of hard anodic oxidation. As a variant, the anodization carried out in the process for manufacturing the diffuser may be a sulfoboric anodic oxidation or sulfotartar anodic oxidation, or a sulfuric anodic oxidation, or a titanium anodic oxidation or a chromic anodic oxidation.

According to a characteristic of the invention, the manufacturing process comprises an additional sealing step, carried out after the anodization step.

According to a characteristic of the invention, the second portion of the diffuser intended to be arranged outside the aqueous urea solution, is at least partially devoid of anodization. Advantageously, the second portion of the diffuser is the area through which the diffuser is held during anodization.

Advantageously, the diffuser is produced by molding and / or machining and / or brazing and / or welding.

The invention will be better understood from the following description, which relates to an embodiment according to the present invention, given by way of nonlimiting example and explained with reference to the appended schematic drawings, in which:

FIG. 1 is a perspective view from above of the heater according to the invention,

FIG. 2 is a bottom perspective view of the heater shown in FIG. 1,

FIG. 3 is an exploded view of the heater according to the invention,

FIG. 4 is an exploded view of a heating block of the heater according to the invention,

FIG. 5 is an exploded view of a heater according to an alternative embodiment,

FIG. 6A is a detailed view in section of the tank according to the invention and comprising a heater according to the invention,

FIG. 6B is a detailed view according to box A of FIG. 6A, and,

- Figure 7 is a partial perspective view of the interior of an aqueous urea solution tank equipped with a heater according to the invention.

According to the invention and as illustrated in particular in FIG. 1, the heater 1 of aqueous urea solution comprises a heat diffuser 2. The diffuser 2 comprises a first portion 2a intended to be immersed in an aqueous urea solution, and a second portion 2b not anodized and intended to be arranged outside the aqueous urea solution, as shown in FIG. 6. The first portion 2a of the diffuser 2 is made of anodized aluminum or anodized aluminum alloy and is configured to be in direct contact with the aqueous urea solution.

In addition, the heater 1 comprises a housing 3 configured to accommodate at least one heating member 5. Of course, in an alternative embodiment, the heater can comprise several housings each comprising one or more heating members independent of each other or no.

In the example illustrated in FIG. 3 and in detail in FIG. 4, the heater comprises a plurality of heating elements 5 grouped in a support 7 and held in a housing 3 of the heater 1 by means of two retaining springs 6 so to form a heating block. In addition, the heating block is in direct contact with the housing 3 of the diffuser 2. Of course, equivalents remain possible at the level of the type of heating elements, at the level of the type of fastening and / or holding elements. allowing the heating element (s) to be maintained in the housing 3 of the heater 1. In this example, the heating elements are thermistors with a positive temperature coefficient but could be resistive tracks or similar elements fulfilling the same function.

As can be seen in FIG. 3, the heater 1 comprises at least one connector element 8 configured to connect the heating element (s) 5 to an electronic card 9, said electronic card 9 being configured to control the heating element (s) 5.

In the example illustrated in FIG. 1, the diffuser 2 comprises a plurality of diffusion fins 4 arranged on the first portion 2a of the diffuser 2.

As can be seen in FIG. 6A, the housing 3 of the diffuser 2 provided for the heater member (s) 5 extends transversely between the first portion 2a of the diffuser 2 and the second portion 2b of the diffuser 2. As a variant shown in FIG. 5, the housing 3 of the heater 1 extends under the diffuser 2 at the second portion 2b of said diffuser 2 and preferably along the second portion 2b of the diffuser 2 so that the housing 3 and the one or more heating elements 5 housed in said housing 3 are never in the so-called wet area of the tank, even partially.

In FIGS. 6A and 7 is shown partially a tank 20 of aqueous urea solution according to the invention in cross section. The reservoir 20 according to the invention comprises an internal volume 21 intended to contain an aqueous urea solution, said internal volume 21 being delimited by at least one upper wall (not shown), a lower wall 22 and a side wall (not shown) ) connecting the upper wall and the lower wall 22.

The tank 20 further comprises a heater 1 according to the invention, said heater 1 being preferably positioned on the bottom wall 22 of the tank 20 or at least near the latter as illustrated in FIG. 7. More particularly, as illustrated in FIG. 6, the first portion 2a of the diffuser 1 being arranged in the interior volume 21 of the reservoir 20. In addition, the second portion 2b of the diffuser 2 is arranged at least partially outside of the reservoir 20. The reservoir 20 comprises an orifice positioning 23 shaped to allow the arrangement of the heater 1 partly in the interior volume 21 of said tank 20 and partly outside the tank 20.

As can be seen in FIG. 6A, the reservoir 20 comprises a seal 10 formed at the level of the positioning orifice 23 so that the second portion 2b of the diffuser 1 is not in contact with the aqueous solution of urea contained in the tank 20. In addition, the connector element 8 of the heater 1 is projecting with respect to the tank 20 and makes it possible to connect the electronic card 9 which is arranged outside of the tank 20 with the heater (s) 5 housed in the housing 3 of the diffuser 2. As a variant, the connector element 8 may not be protruding or else be protruding from the electronic card 9 and not from the heater. FIG. 6B illustrates in detail the separation between the wet zone referenced zone H in FIG. 6B and the dry zone referenced zone S in FIG. 6B. The joint 10 separates the two zones.

The present invention is here explained with reference to an application in a storage system of an aqueous urea solution, but could be applied to any storage system for corrosive fluid for metals requiring thawing.

Of course, the invention is not limited to the embodiments described and shown in the appended figures. Modifications remain possible, in particular from the point of view of the constitution of the various elements or by substitution of technical equivalents, without thereby departing from the scope of protection of the invention.

Claims (10)

1. Heater (1) for corrosive fluid for metals ^- for example an aqueous urea solution comprising: - at least one heat diffuser (2), having at least a first portion (2a) intended to be immersed in a corrosive fluid for metals, for example an aqueous urea solution, and at least a second portion (2b) intended for be arranged outside the corrosive fluid, - at least one heating block comprising at least one heating member (5) configured to heat the corrosive fluid, said diffuser (2) comprising at least one housing (3) in which the at least one heating block is housed at least partially, characterized in that at least the first portion (2a) of the diffuser (2) is made of anodized aluminum or anodized aluminum alloy and is configured to be in direct contact with the corrosive fluid. 2. A heater according to claim 1, wherein the second portion (2b) of the diffuser (2) is at least partially non-anodized. 3. Heater according to any one of claims 1 or 2, wherein the heater block is in direct contact with the housing (3) of the diffuser (2). 4. A heater according to any one of claims 1 to 3, wherein the housing (3) of the diffuser (2) provided for the heater member (s) extends transversely between the first portion (2a) of the diffuser (2) and the second portion (2b) of the diffuser (2). 5. Reservoir (20) for a corrosive fluid for metals, for example an aqueous urea solution, the reservoir (20) comprising: - an interior volume (21) intended to contain a corrosive fluid for metals, for example an aqueous urea solution, said interior volume (21) being delimited by at least one upper wall, a lower wall (22) and a side wall connecting the upper wall and the lower wall (22), a drawing orifice shaped to receive a drawing member for corrosive fluid, it - A heater (1) according to any one of the preceding claims, said heater (1) being positioned on one of the walls of the tank (20), the first portion (2a) of the diffuser (2) of the heater (1) being arranged in the interior volume (21) of the tank (20). 6. Tank according to claim 5, comprising a positioning orifice (23) shaped to allow the arrangement of the heater (1) partly in the interior volume (21) of said tank (20) and partly outside the tank (20) . 7. Tank according to claim 6, comprising a seal (10) formed at the positioning orifice (23), said seal (10) being integrally formed with said positioning orifice (23) of the reservoir or said seal being formed independently of said positioning orifice (23) of the reservoir. 8. Tank according to claim 6, wherein the heater (1) comprises a seal (10) formed at the positioning orifice (23) of the tank, said seal (10) being formed of integral with said heater (1) or said seal being formed independently with respect to said heater (1). 9. A method of manufacturing a heater diffuser according to any one of claims 1 to 4, said method comprising a step of producing the diffuser (2) in a material of aluminum or aluminum alloy type and a step of anodizing on at least a first portion (2a) of said diffuser (2), said first portion (2a) being intended to be immersed in an aqueous urea solution. 10. The manufacturing method according to claim 9, comprising an additional sealing step, carried out after the anodization step. 1/3 2a '8 4